Various methods and semiconductor structures for fabricating an FET device having Nickel atoms implanted in a silicide metal film on a source-drain contact region of the FET device thereby reducing resistance of the source-drain contact region of the FET device. An example fabrication method includes maskless blanket implantation of Nickel atoms across a semiconductor wafer. Nickel atoms can be implanted into silicide metal film of a source-drain contact region of nFET devices, pFET devices, or both, on a semiconductor wafer. Nickel atoms can be implanted into silicide metal film on a source-drain contact region of nFET devices and pFET devices. The silicide metal film on the source-drain contact region of the nFET device being a different material than the silicide metal film on the source-drain contact region of the pFET device.
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1. A method for fabricating a semiconductor structure that reduces source-drain contact resistance in nFET devices and/or pFET devices, the method comprising: implanting Nickel atoms into a Titanium containing silicide metal film on an epitaxially grown source-drain contact region of the at least one FET device thereby reducing interfacial contact resistance of the epitaxially grown source-drain contact region.
2. The method of claim 1 , wherein the at least one FET device is a plurality of FET devices, and the implanting comprises maskless contemporaneous implanting of Nickel atoms in the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of each of the plurality of FET devices.
3. The method of claim 2 , wherein the plurality of FET devices comprises at least one nFET device and at least one pFET device.
4. The method of claim 3 , wherein: the Titanium containing silicide metal film, on the epitaxially grown source-drain contact region of the nFET device, is made of a first silicide metal material; the Titanium containing silicide metal film, on the epitaxially grown source-drain contact region of the pFET device, is made of a second silicide metal material; and the first silicide metal material is different from the second silicide metal material.
5. The method of claim 1 , wherein the at least one FET device is a plurality of FET devices comprising at least one nFET device and at least one pFET device, and wherein the implanting comprises: implanting Nickel atoms in the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one nFET device; and implanting Nickel atoms in the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one pFET device.
6. The method of claim 5 , wherein: the Titanium containing silicide metal film, on the epitaxially grown source-drain contact region of the at least one nFET device, comprises a first silicide metal material; the Titanium containing silicide metal film, on the epitaxially grown source-drain contact region of the at least one pFET device, comprises a second silicide metal material; and the first silicide metal material is different from the second silicide metal material.
7. The method of claim 1 , wherein the implanting comprises: beamline implanting of Nickel atoms into the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one FET device.
8. The method of claim 1 , wherein the implanting comprises: plasma doping of Nickel atoms into the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one FET device.
9. A method for fabricating a semiconductor structure that reduces source-drain contact resistance in nFET devices and/or pFET devices, the method comprising: depositing a very thin film of Nickel on a Titanium containing silicide metal film on an epitaxially grown source-drain contact region of the at least one FET device; and using grain boundary diffusion of the Nickel atoms from the very thin film of Nickel into the Titanium containing silicide metal film to transfer Nickel atoms from the very thin film of Nickel to an interface between the Titanium containing silicide metal film and the epitaxially grown source-drain contact region, thereby reducing interfacial contact resistance of the source-drain contact region.
10. The method of claim 1 , further comprising: alloying Titanium containing silicide metal material with a few atomic percent of Nickel atoms to form Titanium Nickel alloy silicide metal material; depositing this alloy to form a Titanium Nickel alloy silicide metal film on the epitaxially grown source-drain contact region of an FET device; and using grain boundary diffusion of Nickel atoms in the Titanium Nickel alloy silicide metal film to transfer the Nickel atoms to an interface between the Titanium Nickel alloy silicide metal film and the epitaxially grown source-drain contact region of the FET device, thereby reducing interfacial contact resistance of the source-drain contact region.
11. A method for fabricating a semiconductor structure that reduces source-drain contact resistance in nFET devices and pFET devices, the method comprising: maskless contemporaneous implanting of Nickel atoms into a Titanium containing silicide metal film on epitaxially grown source-drain contact regions of a plurality of FET devices including at least one nFET device and at least one pFET device, thereby reducing interfacial contact resistance of the epitaxially grown source-drain contact region of each of the plurality of FET devices.
12. The method of claim 11 , wherein: the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one nFET device is made of a first silicide metal material; the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one pFET device is made of a second silicide metal material; and the first silicide metal material is different from the second silicide metal material.
13. The method of claim 11 , wherein the maskless contemporaneous implanting comprises: beamline implanting of Nickel atoms into the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one nFET device and the epitaxially grown source-drain contact region of the at least one pFET device.
14. The method of claim 11 , wherein the maskless contemporaneous implanting comprises: plasma doping of Nickel atoms into the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one nFET device and the epitaxially grown source-drain contact region of the at least one pFET device.
15. The method of claim 11 , further comprising: depositing a very thin film of Nickel on the Titanium containing silicide metal film on the epitaxially grown source-drain contact regions of the plurality of FET devices including the at least one nFET device and the at least one pFET device; and using grain boundary diffusion of Nickel atoms from the very thin film of Nickel into the Titanium containing silicide metal film to transfer Nickel atoms from the very thin film of Nickel to an interface between the Titanium containing silicide metal film and the epitaxially grown source-drain contact region of each of the plurality of FET devices, thereby reducing interfacial contact resistance of the source-drain contact region.
16. The method of claim 11 , further comprising: depositing a very thin film of Nickel on the Titanium containing silicide metal film on the epitaxially grown source-drain contact region of the at least one nFET device and on the epitaxially grown source-drain contact region of the at least one pFET device; and using grain boundary diffusion of the Nickel atoms from the very thin film of Nickel into the Titanium containing silicide metal film to transfer implanted Nickel atoms to: an interface between the Titanium containing silicide metal film and the epitaxially grown source-drain contact region of the at least one nFET device, thereby reducing interfacial contact resistance of the source-drain contact region of the at least one nFET device; and an interface between the Titanium containing silicide metal film and the epitaxially grown source-drain contact region of the at least one pFET device, thereby reducing interfacial contact resistance of the source-drain contact region of the at least one pFET device, and wherein before depositing the very thin film of Nickel on the Titanium containing silicide metal film, the Titanium containing silicide metal film contains no Nickel atoms.
17. The method of claim 11 , further comprising: alloying Titanium containing silicide metal material with a few atomic percent of Nickel atoms to form Titanium Nickel alloy silicide metal material; depositing this alloy to form a Titanium Nickel alloy silicide metal film on the epitaxially grown source-drain contact regions of the plurality of FET devices; and using grain boundary diffusion of Nickel atoms in the Titanium Nickel alloy silicide metal film to transfer the Nickel atoms to an interface between the Titanium Nickel alloy silicide metal film and the epitaxially grown source-drain contact region of each of the plurality of FET devices, thereby reducing interfacial contact resistance of the source-drain contact region.
18. The method of claim 11 , wherein before the maskless contemporaneous implanting of Nickel atoms into the Titanium containing silicide metal film, the Titanium containing silicide metal film contains no Nickel atoms.
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September 1, 2016
May 28, 2019
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